JP7194998B2 - Plant cultivation container, plant cultivation facility, and plant cultivation method - Google Patents

Description

The present invention relates to a plant cultivation container, a plant cultivation facility, and a plant cultivation method.

Vegetables that are sold in containers, such as radish sprouts sold in supermarkets, are usually grown in a different location and then stored in the container and sealed, or It is sealed after cultivation in Unlike this, Patent Documents 1 to 3 describe techniques for cultivating plants such as vegetables in a sealed state in a container. The techniques described in Patent Documents 1 to 3 are very hygienic because the plants are not handled by human hands until the consumer opens the container.

Special table 2015-534463 (published on December 3, 2015) Japanese Patent Application Laid-Open No. 2010-29115 (published on February 12, 2010) Japanese Patent Application Laid-Open No. 10-56886 (published on March 3, 1998)

However, in the techniques described in Patent Documents 1 and 2, since the liquid is supplied from the outside, there is a risk that bacteria may enter the container as the liquid is supplied. In addition, since the technology described in Patent Document 3 cannot control the cultivation environment such as moisture and humidity in the closed container, the plants that can be cultivated are limited to shade-loving plants growing in wetlands.

Moreover, if the humidity of the cultivation environment cannot be controlled as in the technique described in Patent Document 3, there is a risk that the excessive humidity will continue and the growth of the plant will slow down. As a result, there is also the problem that efficient production is hindered. In order to solve the excessive humidity, it is usually considered to make the cultivation environment breathable and remove excess water vapor, but even the water necessary for plant growth is removed, and the lack of water is removed. It needs to be supplied, and it is difficult to cultivate in a sealed state.

One aspect of the present invention has been made to solve the above problems, and an object thereof is to realize a technique for cultivating a plant in a closed container in a cultivation environment suitable for the plant.

In order to solve the above problems, the present invention provides, for example, inventions according to the following aspects.
1) A plant cultivation container containing a plant propagule and water for at least one cultivation cycle in a closed container.
2) The plant cultivation container according to 1), wherein the water is a nutrient solution.
3) Plant cultivation container according to 1) or 2), which is provided with a carbon dioxide source.
4) The plant cultivation container according to 3), wherein the carbon dioxide is supplied by yeast fermentation.
5) The plant propagule is seeds, bulbs, tubers, young seedlings, spores, mycelium, and callus, and the plant propagule is separated from the water and stored in the closed container, 1) to 4. ).
6) The plant cultivation container according to 5), wherein the plant propagation material is a vegetable seed.
7) The plant cultivation container according to any one of 1) to 6), wherein the closed container does not have an opening for introducing water and/or fertilizer from the outside.
8) The plant cultivation container according to any one of 1) to 7), which is equipped with a humidity sensor.
9) A plant cultivation facility comprising a plurality of the plant cultivation containers according to any one of 1) to 8) and a cooling device for cooling the plant cultivation containers.
10) A plant cultivating method for cultivating a plant, the plant cultivating method including the step of storing and cultivating the plant in a closed container, and artificially cooling the closed container to lower the humidity in the closed container.
11) The method of cultivating a plant according to 10), wherein the step is performed by cooling a portion of the outer surface of the closed container.
12) The plant cultivation method according to 10) or 11), which is carried out using the plant cultivation container according to any one of 1) to 8) or the plant cultivation facility according to 9).

According to one aspect of the present invention, plants can be cultivated without externally supplying liquid to the plants in the closed container.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the outline|summary of the plant cultivation container which concerns on one Embodiment of this invention. It is a figure which shows the outline|summary of another example of the plant cultivation container which concerns on one Embodiment of this invention. BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows the outline|summary of the plant cultivation facility which concerns on one Embodiment of this invention. It is a figure which shows the result of having cultivated the seed using the plant cultivation container which concerns on one Embodiment of this invention. It is a figure which shows the result of the saturation when the seed is cultivated using the plant cultivation container which concerns on one Embodiment of this invention. It is a figure which shows the result of the saturation when another seed is cultivated using the plant cultivation container which concerns on one Embodiment of this invention.

[Plant cultivation container]
A plant cultivation container according to one embodiment of the present invention will be described with reference to FIGS. A plant cultivation container 10 according to one embodiment of the present invention stores a plant propagation material 1 and water for at least one cultivation cycle in a closed container 2 . FIG. 1 is a diagram showing an outline of a plant cultivation container according to one embodiment of the present invention. FIG. 2 is a diagram showing an overview of another example of the plant cultivation container according to one embodiment of the present invention.

Since the plant cultivation container 10 grows the plant propagation material 1 in the closed container 2, the invasion of contaminants such as fungi from the outside is suppressed, and the plant propagation material 1 is grown in a sterile, sterilized, or aseptic environment. It is possible to prevent the plant propagation material 1 and the grown plant from being affected by the disease. In the plant cultivation container 10, since the plant propagule 1 is stored in the closed container 2, for example, by cooling from the outside a part of the closed container 2 warmed by sunlight, the temperature inside the closed container 2 is reduced. and humidity can be adjusted. As a result, by using the plant cultivation container 10, it is possible to prevent the growth of plants from slowing down due to continued overhumidity, and to realize efficient production of plants.

(plant propagule)
In one embodiment of the present invention, the plant propagation material 1 is intended to be plant propagation material and may be, for example, plant seeds, bulbs, tubers, seedlings, spores, mycelium, callus, and the like. In addition, the above-described form of the plant propagation material 1 is intended to be the form at the time when the manufacturer of the plant cultivation container 10 ships the plant cultivation container 10 . When the plant cultivation container 10 reaches the final consumer (general consumer, restaurant, etc.), the plant propagation material 1 may have grown and changed its shape.

The plant propagation material 1 may be a propagation material such as vegetables, mushrooms, and flowers. The plant propagation material 1 may be a vegetable seed. The plant propagule 1 may be propagation materials such as herbs such as basil and coriander, leafy vegetables such as lettuce and spinach, and root vegetables such as radishes and carrots. Moreover, the plant propagule 1 is preferably a seed of a plant belonging to the Brassicaceae family, which takes a relatively short time to germinate.

The number of plant propagules 1 stored in the closed container 2 is preferably a number that does not require operations such as thinning and flower picking, and is preferably 1 or more and 10 or less, for example. The plant propagule 1 to be stored in the closed container 2 is preferably of a size that allows the grown plant to fit inside the closed container 2 .

The plant propagule 1 may be stored in the sealed container 2 in a state of being placed on the medium 3 or planted in the medium 3 . As the medium 3, for example, soil, sponge, coconut shell, hydroball, vermiculite, rock wool, etc. can be used.

In one embodiment of the present invention, the culture medium 3 is housed in a cylindrical body that is open at the top and bottom, and the opening located on the lower side opposite to the upper side where the plant propagule 1 is planted is closed with non-woven fabric, mesh, or the like. It is preferable that it is dry. By covering the lower side of the cylindrical body with a non-woven fabric, a mesh, or the like, it is possible to prevent medium leakage while allowing evaporation and water supply.

The plant propagule 1 and medium 3 are preferably sterile, sterile or aseptic. The plant propagule 1 and the culture medium 3 are preferably subjected to sterilization before or after being stored in the closed container 2 .

(closed container)
The sealed container 2 is made of a material that is impermeable or difficult to permeate gas and liquid. The closed container 2 has an opening for storing the plant propagation material 1 and water inside, and the opening may be sealed after storing the plant propagation material 1 and water inside. The sealed container 2 is preferably completely sealed after the plant propagation material 1 and water are stored therein. Here, "completely sealed" means a state in which no gas or liquid enters or exits unless intentionally injected or discharged.

The sealed container 2 is made of a material that allows light to pass therethrough and is impermeable or difficult to pass gas and liquid. The material forming the sealed container 2 is preferably lightweight and rigid resin. Examples of materials for forming the sealed container 2 include polyvinyl chloride, polyethylene, polypropylene, polyethylene terephthalate, biodegradable plastics, and the like. Moreover, the sealed container 2 is preferably transparent so that the inside can be easily viewed in a sealed state. The closed container 2 may be bag-shaped or box-shaped.

The sealed container 2 may be provided with a supply port for receiving supply of carbon dioxide from a carbon dioxide supply source, which will be described later. A carbon dioxide supply port provided in the sealed container 2 may be provided with a valve so that the supply port may be completely closed when carbon dioxide is not supplied. Further, a configuration in which the carbon dioxide supply source 4 is provided in the sealed container 2 may be employed.
The sealed container 2 may include an exhaust section (not shown) for exhausting oxygen gas produced by photosynthesis. In particular, when the plant propagule 1 grows into a large plant, excessive oxygen gas is generated, so it is preferable that the sealed container 2 has an exhaust section. As the exhaust part, for example, a cock dedicated to exhaust with a check valve may be provided, whereby the oxygen gas in the closed container 2 can be exhausted while preventing outside air from flowing into the closed container 2 .

Although not limited to this, the closed container 2 does not have an opening for introducing water and/or fertilizer from the outside in a preferred form. Therefore, after the plant propagation material 1 and water are housed in the closed container 2 and the opening is sealed, water and/or fertilizer is not introduced from the outside. Thus, since the closed container 2 does not have an opening for introducing water and/or fertilizer from the outside, it is possible to prevent contaminants such as bacteria from entering the inside.

The closed container 2 is preferably sterile, sterile or aseptic. It is preferable that the sealed container 2 is subjected to sterilization before or after storing the plant propagule 1 and water. By using the closed container 2, the plant propagule 1 can be grown in a sterile, sterilized, or aseptic environment.

In addition, the sealed container 2 is sealed after injecting air from which contaminants have been removed through a filter or the like in advance, or the plant propagule 1 and water are stored in the sealed container 2 and sealed. is preferably performed in a clean room. Carbon dioxide from which contaminants have been removed in advance may be injected into the sealed container 2 .

The closed container 2 may be of a size capable of accommodating a plant grown with one plant propagation material 1, and may also accommodate a plant with two or more and ten or less plant propagation materials 1 grown thereon. It may be as large as possible. Therefore, the internal volume of the closed container 2 can be 1000 cm ³ or more and 125000 cm ³ or less, preferably 3000 cm ³ or more and 30000 cm ³ or less.

(water)
The water for one cultivation cycle stored in the closed container 2 is from the start of cultivation of the plant propagule 1 to germination, to the growth of true leaves, to the formation of flower buds, to flowering, Or until fruit set is considered as one cultivation cycle, and water is intended as needed during that one cultivation cycle. When the plant propagating body 1 is a propagation material for vegetables, the sealed container 2 may contain water required from the start of cultivation to the first harvest.

When the plant propagule 1 is a propagation material for vegetables, the amount of water for one cultivation cycle is preferably 100 mL or more and 500 mL or less. For example, if the plant propagule 1 is spinach seed, one cultivation cycle for growing 100 g of spinach may be at least 100 g of water. The water for one cultivation cycle can be 150 mL or more, 200 mL or more, or 250 mL or more, and can be 500 mL or less, 450 mL or less, or 400 mL or less.

The water stored in the sealed container 2 may be a nutrient solution. The nutrient solution is a liquid containing nutrients for growing the plant propagation material 1, and examples of the nutrients include nitrogen, iron, and phosphorus. Also, the water stored in the sealed container 2 may be a buffer solution. The water may be stored in the plant cultivation container 10 in a state of being contained in the culture medium 3 described later, or may be contained in another container with which part of the plant propagation material 1 (for example, roots) can come into contact. It may be stored in the sealed container 2 in a state where it is closed.

The water stored in the closed container 2 is preferably sterile, sterilized, or aseptic. The water stored in the sealed container 2 is preferably sterilized before or after storage.

The water stored in the sealed container 2 may be enclosed in a bag and stored in the sealed container 2 in a form separated from the plant propagation material 1 . In this case, water may be supplied to the plant propagation material 1 by breaking the bag from the outside of the closed container 2 when cultivation of the plant propagation material 1 is started.

(source of carbon dioxide)
The plant growing container 10 may comprise a source 4 of carbon dioxide. The carbon dioxide supply source 4 may be an internal attachment provided inside the closed container 2 or an external attachment provided outside the closed container 2 .

If the carbon dioxide source 4 is internal, the carbon dioxide source 4 is preferably sterile, sterile, or aseptic. The carbon dioxide supply source 4 is preferably sterilized before or after storage in the sealed container 2 .

When the carbon dioxide supply source 4 is external, the carbon dioxide supply source 4 is connected to the supply port provided in the sealed container 2 via the pipe 5 . The pipe 5 connected to the carbon dioxide supply source 4 is preferably provided with a check valve 6 for preventing backflow of carbon dioxide. When the carbon dioxide supply source 4 is external, the carbon dioxide supply source 4 may be separated from the sealed container 2 before the plant cultivation container 10 is shipped, and only the plant cultivation container 10 may be shipped.

The carbon dioxide source 4 may supply carbon dioxide produced by yeast fermentation. Thus, the carbon dioxide source 4 comprises yeast and a container containing the yeast, and may further comprise a medium for culturing the yeast. The type of yeast provided in the carbon dioxide supply source 4 is not limited as long as it is a budding yeast that produces carbon dioxide by alcoholic fermentation, and is, for example, Saccharomyces cerevisiae. A medium for culturing yeast may be any medium that supplies sugar to yeast, for example, a sugar agar medium.

(Humidity sensor)
The plant cultivation container 10 may be equipped with a humidity sensor. The humidity sensor 101 may record or manage humidity measured by a known hygrometer, or may include a thermohygrometer that measures both humidity and temperature. The humidity sensor 101 may be attached externally or internally to the closed container 2 , and may be separated from the closed container 2 when the plant cultivation container 10 is shipped. Only the sensor 102 of the humidity sensor 101 may be provided inside the sealed container 2 .

If the humidity sensing part 101 or the sensor 102 is provided in the closed container 2, the humidity sensing part 101 and the sensor 102 are preferably sterile, sterile or aseptic. The humidity sensor 101 and the sensor 102 are preferably sterilized before or after they are stored in the closed container 2 .

In addition, the plant cultivation container 10 may be provided with other sensing parts such as a temperature sensing part and a contaminant sensing part either externally or internally.

(Cultivation method using plant cultivation container 10)
A cultivation method using the plant cultivation container 10 will be described with reference to FIG. As shown in FIG. 1, the plant cultivation container 10 is placed in an environment irradiated with sunlight or artificial light, and carbon dioxide is continuously supplied. Therefore, the plant cultivation container 10 is warmed during the daytime or during irradiation with artificial light, and the temperature inside the closed container 2 rises. In the cultivation method using the plant cultivation container 10 , the part of the plant cultivation container 10 warmed in this manner is artificially cooled by the cooling device 7 . As a result, the temperature inside the sealed container 2 is lowered and the humidity is lowered.

Cooling of the sealed container 2 is performed by cooling a part of the outer surface of the sealed container 2 . Examples of the cooling device 7 include an AC fan, a Peltier element, a coolant, and the like that cools by blowing air. In addition, when cultivating a plurality of plant cultivation containers 10 at once, the sealed containers 2 are arranged and the cold air from the cooling device 7 is flowed in the direction along the rows of the sealed containers 2, thereby increasing the number of sealed containers. The container 2 may be partially cooled at once.

By cooling the closed container 2, the inside of the closed container 2 is condensed, the humidity is adjusted, and the transpiration from the plant in which the plant propagule 1 has grown can be promoted. In addition, by cooling the sealed container 2 (especially partially), the over-humidity inside the sealed container 2 can be eliminated. Moreover, since a part of the sealed container 2 is cooled, the temperature inside the sealed container 2 does not drop excessively, and both the temperature and the humidity can be controlled. Furthermore, the water generated in the sealed container 2 due to dew condensation returns to the plant propagation material 1 (or the grown plant body) or the culture medium 3 and is used for the growth of the plant propagation material 1 (or the grown plant body). .

In the conventional cultivation method, the cultivation environment is provided with air permeability to eliminate excessive humidity, and as a result, the shortage of water is supplied from the outside. On the other hand, according to the plant cultivation container 10 according to one embodiment of the present invention, both the temperature and the humidity can be adjusted only by cooling the closed container 2, so the temperature can be lowered while eliminating the excessive humidity. Not too much. As a result, according to the plant cultivation container 10 according to one embodiment of the present invention, it is possible to prevent slowing down of growth of the plant propagule due to continuation of the excessively humid state, and to realize efficient plant production. In addition, since it is not necessary to supply water into the closed container 2 from the outside, it is possible to prevent contaminants from entering the closed container 2 due to the supply of water, and the plant propagule 1 or the grown plant during cultivation is prevented. can be prevented from getting sick.

In the cultivation method using the plant cultivating container 10, if the things necessary for the growth of the plant propagation material 1 are first placed in the sealed container 2, the plant grown from the plant propagation material 1 is kept sealed until harvesting. OK. Therefore, for example, even when the plant cultivation container 10 is placed in a restaurant to cultivate the plant propagation material 1, it is hygienic.

In addition, in the cultivation method using the plant cultivation container 10, it is only necessary to manage the light irradiation and cooling of the plant cultivation container 10, so that it is possible to save labor in the cultivation work and reduce the cost related to the cultivation facility. be able to.

If the temperature inside the plant cultivation container 10 drops too much at night or when no light is applied, the temperature may be raised by heating the plant cultivation container 10 with a heater or the like. Even if the humidity in the plant cultivation container 10 rises to nearly 100% at night or when light is not irradiated, the inside of the plant cultivation container 10 is maintained in a sterilized state, so the risk of disease damage due to overhumidity is low.

In the cultivation method using the plant cultivation container 10, the closed container 2 is cooled by the cooling device 7 so that the saturation in the closed container 2 is suitable for the growth of the plant body. In the cultivation method using the plant cultivation container 10, it is preferable that the saturation difference in the closed container 2 is 3 g/m ³ or more and 6 g/m ³ or less.

Cooling by the cooling device 7 may be performed according to the humidity measured by the humidity sensor 101 . That is, when the saturation difference calculated from the temperature and humidity measured by the humidity sensing unit 101 is outside a predetermined numerical range, the cooling device 7 is driven to start cooling, and the humidity sensing unit 101 measures The cooling device 7 may be controlled so as to stop the cooling device 7 and terminate cooling when the saturation difference calculated from the measured temperature and humidity falls within a predetermined numerical range.

As soon as the sunlight or artificial light starts to be irradiated, the temperature inside the closed container 2 starts to rise, and as soon as the irradiation of the sunlight or artificial light is stopped, the temperature inside the closed container 2 starts to drop. Alternatively, the irradiation of artificial light and the cooling by the cooling device 7 may be controlled to start (ON) at the same time and end (OFF) at the same time. Moreover, when the temperature in the plant cultivation container 10 drops too much when the irradiation of sunlight or artificial light is stopped, the plant cultivation container 10 may be heated by a heater or the like to raise the temperature.

The cultivation period in the cultivation method using the plant cultivation container 10 is 15 days or more and 50 days or less when the plant propagation material 1 is seeds of herbs such as basil and coriander, and the plant propagation material 1 is lettuce or spinach. If the plant propagation material 1 is a seed of a leafy vegetable, it may be 25 days or more and 50 days or less, and if the plant propagule 1 is a root vegetable seed such as radish or carrot, it may be 50 days or more and 70 days or less.

In the cultivation method using the plant cultivation container 10, when cultivating by irradiating artificial light, the plant cultivation container 10 is placed in the plant cultivation facility 100, and the light emitting unit 103 provided in the plant cultivation facility 100 artificially emits light. Light may be applied. The light emitting unit 103 can be, for example, a fluorescent lamp. By cultivating plants using the plant cultivation container 10 in the plant cultivation facility 100 having the light emitting unit 103, light irradiation and temperature and humidity control can be performed more accurately.

[Plant cultivation facility]
A plant cultivation facility according to one embodiment of the present invention will be described with reference to FIG. A plant cultivation facility 100 according to one embodiment of the present invention includes a plurality of plant cultivation containers 10 according to one embodiment of the present invention and a cooling device 7 for cooling the plant cultivation containers. FIG. 3 is a diagram showing an outline of a plant cultivation facility according to one embodiment of the present invention.

Since the plant cultivation facility 100 includes a plurality of plant cultivation containers 10, a plurality of plant propagules 1 can be cultivated. Therefore, a large amount of plant propagation material 1 can be cultivated at the same time. In addition, only by cooling the plant cultivation container 10 from the outside using the cooling device 7, not only can the humidity suitable for the growth of the plant propagation material 1 be obtained, but also the growth is possible without supplying water from the outside. You can get the water you need. In addition, since it is not necessary to supply water into the closed container 2 from the outside, it is possible to prevent contaminants from entering the closed container 2 accompanying the supply of water, and prevent the plant propagule 1 from being affected during cultivation. be able to. Examples of the plant cultivation facility 100 include glass greenhouses, vinyl greenhouses, and the like.

The plant cultivation facility 100 may further include a light emitting unit that irradiates the plant cultivation container 10 with artificial light. In addition, since the plant cultivation container 10 enables cultivation while suppressing the invasion of contaminants such as bacteria from the outside by the closed container 2, the inside of the plant cultivation facility 100 does not need to be a clean room.

[Plant cultivation method]
A plant cultivation method according to an embodiment of the present invention is a plant cultivation method for cultivating a plant, wherein the plant is stored and cultivated in a closed container, and the humidity in the closed container is reduced by artificial cooling. Including lowering step. Further, in the plant cultivation method according to one embodiment of the present invention, the above process may be performed by cooling a part of the outer surface of the closed container. That is, a plant cultivation method according to an embodiment of the present invention is a plant cultivation method that is performed using the above-described plant cultivation container or the above-described plant cultivation facility. Therefore, the description of the plant cultivation method according to one embodiment of the present invention conforms to the description of the plant cultivation container described above, the description of the cultivation method using the plant cultivation container described above, and the description of the plant cultivation facility.

[Mode of distribution]
Although not particularly limited, for example, the following forms of distribution are conceivable.
In the state of the plant propagation material 1 or at the initial stage when the plant propagation material 1 starts to grow, the plant cultivation container 10 is supplied from the manufacturer by 1) the plant cultivation facility 100 or 2) for example, a home center, a seedling store, etc. delivered to retailers or wholesalers, etc. At the stage when the plant propagule 1 is about to be harvested or has become a harvestable plant, the plant cultivation container 10 handles 1) end consumers, 2) restaurants, and 3) perishables from the plant cultivation facility 100. Delivered to retailers or wholesalers.

The present invention is not limited to the above-described embodiments, but can be modified in various ways within the scope of the claims, and can be obtained by appropriately combining technical means disclosed in different embodiments. is also included in the technical scope of the present invention.

An embodiment of the invention is described below.

Sweet basil (takii seedlings) and coriander (takii seedlings) seeds were purchased and grown as propagules in separate plant growth containers. A nylon plastic bag (Fukusuke Industry No. 25) was used as a closed container. The seeds were placed on a hydroball (foamed brick for gardening, Hydroculture Nakatama, Takamura Co., Ltd.), and 200 mL of EC1 (manufactured by Otsuka Fertilizer), which is a culture solution, was supplied to the hydroball.

From the carbon dioxide supply source provided outside the nylon plastic bag, yeast (Super Camellia Dry Yeast, Nihon Co., Ltd.) was added to sugar agar (sugar: Spoon Shirato, Mitsui Sugar Co., Ltd., agar: Kantenpapa, Kanten Cook, Ina Food Industry Co., Ltd.). The carbon dioxide generated by culturing the fresh flour) was supplied into the nylon plastic bag. A temperature and humidity sensor (thermo recorder, RS-12, Especmic) provided in the nylon plastic bag was used to measure the saturation difference in the nylon plastic bag.

The seeds on the hydroball supplied with the culture medium were placed in a nylon plastic bag, and the opening was sealed. One of the sealed nylon plastic bags is placed in a constant temperature chamber (Yamato Incubator IS400) with a width of 45 cm, a depth of 50 cm, and a height of 45 cm. irradiated with light. The amount of light in the sealed container was 400 μmol·m ⁻² ·s ⁻¹ .

Cooling of the nylon plastic bag from the outside was performed by blowing air (0° C.) outside the constant temperature chamber into the constant temperature chamber with an AC fan (MU1225S, 1.6 m ³ /min). The temperature inside the constant temperature chamber was set to 27° C., but the door of the constant temperature chamber was always half-opened for ventilation by an AC fan. The states of carbon dioxide supply, light irradiation, and cooling are illustrated in FIG. 4(d).

(a) to (d) in FIG. 4 are diagrams showing the results of cultivating seeds using the plant cultivation container according to one embodiment of the present invention. As shown in FIG. 4(a), when the cultivation of basil seeds was started in a nylon plastic bag, as shown in FIG. As shown in (c) in 4, germination was confirmed two weeks after the start of cultivation. It was found that the seeds germinated without externally supplying water or the like into the nylon plastic bag. Sweet basil grew to a plant height of about 5 to 8 cm 21 days after sowing, and coriander 14 days after sowing. Lettuce seeds (takii seedlings) were also cultivated in the same manner as sweet basil and coriander, and it was confirmed that true leaves developed 10 days after seeding.

FIG. 5 shows the results of saturation when seeds are cultivated using the plant cultivation container according to one embodiment of the present invention. As shown in FIG. 5, the temperature inside the nylon plastic bag containing the basil seeds rises to 25-27° C. At the same time, it is cooled by the AC fan. The saturation difference in the bag could be in the range of 3 g/m ³ or more and 4 g/m ³ or less. It was found that the filling inside the nylon plastic bag can be properly maintained only by cooling the nylon plastic bag from the outside.

FIG. 6 shows the results of saturation when other seeds were cultivated using the plant cultivation container according to one embodiment of the present invention. When coriander seeds are grown in a nylon plastic bag, as shown in FIG. When illumination and ventilation are turned on and artificial light irradiation and cooling are performed, the saturation difference is maintained within an appropriate range. Such saturation variation was associated with changes in the temperature and humidity inside the nylon plastic bag. It was found that by only cooling the nylon plastic bag from the outside, even when other seeds were used, the filling in the nylon plastic bag could be appropriately maintained.

INDUSTRIAL APPLICABILITY The present invention can be used in fields such as agriculture and food.

REFERENCE SIGNS LIST 1 plant propagule 2 sealed container 4 carbon dioxide supply source 7 cooling device 10 plant cultivation container 100 plant cultivation facility 101 humidity sensor

Claims (14)

A plant cultivation container containing a plant propagule placed on or planted on a medium and water for at least one cultivation cycle in a closed container,
The water for at least one cultivation cycle is water of 100 mL or more and 500 mL or less,
The plant propagule is a propagation material such as vegetables, mushrooms, and flowers, and is a seed, bulb, tuber, seedling, spore, mycelium, or callus,
The plant cultivation container, wherein the medium is soil, sponge, coconut shell, hydroball, vermiculite, or rock wool . The plant cultivation container according to claim 1, wherein the water is a nutrient solution. 3. Plant cultivation container according to claim 1 or 2, comprising a source of carbon dioxide. 4. Plant cultivation container according to claim 3, wherein the carbon dioxide is supplied by yeast fermentation. The plant cultivation container according to any one of claims 1 to 4, wherein the plant propagation material is separated from the water and stored in the closed container. The plant cultivation container according to claim 5, wherein the plant propagation material is a vegetable seed. The plant cultivation container according to any one of claims 1 to 6, wherein the closed container does not have an opening for introducing water and/or fertilizer from the outside. 8. Plant cultivation container according to any one of claims 1 to 7, comprising a humidity sensor. A plant cultivation facility comprising a plurality of the plant cultivation containers according to any one of claims 1 to 8 and a cooling device for cooling the plant cultivation containers. A plant cultivation method for cultivating plants,
The plant is stored and cultivated in an airtight container,
A step of artificially cooling to reduce the humidity in the closed container ,
performing the step by cooling a portion of the outer surface of the closed container;
plant cultivation method. The plant cultivation method according to claim 10, which is carried out using the plant cultivation container according to any one of claims 1 to 8 or the plant cultivation facility according to claim 9. The plant cultivation method according to claim 10 or 11, wherein the airtight container is cooled according to the humidity inside the airtight container. A plant propagule and water for at least one cultivation cycle are stored in a closed container,
The water for at least one cultivation cycle is water of 100 mL or more and 500 mL or less,
The plant cultivation container, wherein the plant propagation material is a seed, a bulb, a tuber, a young seedling, a spore, a mycelium, or a callus, and the plant propagation material is separated from the water and stored in the closed container. A plant propagule and water for at least one cultivation cycle are stored in a closed container,
The water for at least one cultivation cycle is water of 100 mL or more and 500 mL or less,
A plant growing container comprising a humidity sensor.

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